Monitor system for coating apparatus

ABSTRACT

A spray monitoring device analyzes images obtained from a beam passing through a spray pattern applying a spray to a substrate, and identifies discontinuities in the image as indicative of a discontinuity in a spray pattern. The spray pattern is produced by a plurality of nozzles spaced apart across the substrate for applying a suitable coating thereto. The beam is produced by a laser, that preferably has a collimator for distributing the beam intensity. The beam is imaged by a camera that provides a constant image to a computers where the scattering of beam light by the spray pattern is processed by image processing software and optionally provided to a user interface for analysis. Discontinuities detected by the user or software indicate faulty spray nozzles and may trigger remedial action.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Divisional of U.S. application Ser. No. 11/620,379, filed on Jan. 5, 2007, entitled “MONITOR SYSTEM FOR COATING APPARATUS,” which is a Continuation of PCTCA051123 filed on Jul. 18, 2005, the entirety of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to apparatus and methods of monitoring the application of a fluid to a substrate.

BACKGROUND

It is frequently necessary to coat a substrate with a fluid during a manufacturing process. The application of the coatings may be for protective purposes or as part of the manufacturing process, and it is frequently essential that the fluid be applied in a uniform manner. Many manufacturing processes produce a substrate in a continuous manner as a web, and require the coating to be applied to the web as it is produced. A typical application for such coating is in the steel industry where an oil based lubricant is applied to a moving metal strip. The lubricant is required to assist in the further processing of the steel strip, and, accordingly, the film thickness of the lubricant must be uniform. Failure to provide a uniform coating will lead to inconsistencies in the further manufacturing process and the possibility of damage to the manufacturing equipment.

The coating is frequently applied through an array of spray nozzles positioned in the path of the substrate. Each of the spray heads has a number of nozzles that in ideal circumstances will produce a uniform spray pattern and distribute the sprayed fluid evenly. There is a possibility that the nozzles may become blocked or experience wear, which can produce an uneven spray pattern, and consequently an uneven coating. When such a defect is discovered, it may be necessary to call back significant quantities of material that have been processed with a possibly defective coating. Therefore, the efficacy of the coating is typically inspected periodically, but usually by manual observation. This is both time consuming and inconsistent, and requires significant skill on the part of the operator to recognize the existence of a fault.

It is therefore an object of the present invention to provide a method and apparatus in which the above disadvantages are obviated or mitigated.

SUMMARY OF THE INVENTION

In general terms, the present invention provides a system or method in which a coherent light source, typically a laser, is directed through a spray pattern. A camera is positioned to record the image of a beam as it propagates through the spray pattern and analyze the image to determine spray uniformity and continuity of the spray pattern.

Preferably the camera is integrated with the control system for the apparatus to provide an indication of inconsistent spraying and initiate remedial action.

In one aspect, the present invention provides a method of monitoring the application of coating to a substrate from a plurality of nozzles spaced apart across the substrate. The method comprises the steps of projecting a beam of coherent radiation through a spray of coating from said nozzles, obtaining an image of the beam as it propagates through the spray, and processing the image to determine variations in a characteristic indicative of the presence of the spray.

In another aspect, the present invention provides a system for monitoring the application of coating to a surface of a substrate, the coating being applied as a spray from a plurality of nozzles spaced apart across the substrate. The system comprises a coherent radiation source arranged to direct a beam of coherent radiation through the spray; an imaging device for obtaining an image of the beam as it propagates through the spray; and a computing device having a processor and being connected to the imaging device, the processor executing image processing software to process the image in order to determine variations in a characteristic indicative of the presence of the spray.

In yet another aspect, the present invention provides an apparatus for monitoring the application of coating to a substrate, the coating being applied by a plurality of nozzles spaced apart across the substrate. The apparatus comprises a coating station having a feeder for continuously feeding the substrate through the apparatus; at least one sprayhead connected to the coating station and positioned a predetermined distance from the substrate, the sprayhead having a plurality of nozzles, the nozzles being connected to a source of coating to enable coating to be fed through the nozzles to produce a spray of coating, the spray of coating being applied to a surface of the substrate; at least one coherent radiation source arranged to direct a beam of coherent radiation through the spray as it is applied to the substrate; an imaging device for obtaining an image of the beam as it propagates through the spray; and a computing device having a processor for processing the image to determine variations in a characteristic indicative of the presence of the spray.

BRIEF DESCRIPTION OF THE DRAWINGS

An embodiment of the invention will now be described by way of example only with reference to the accompanying drawings in which:

FIG. 1 is a perspective view of a coating apparatus;

FIG. 2 is a view on the line II-II of FIG. 1;

FIG. 3A and FIG. 3B are representations of images obtained from the apparatus of FIG. 1 under different operating conditions;

FIG. 4 is a screen shot of an interface showing the information obtained; and

FIG. 5 is a flow chart indicating the processing of data obtained film the images shown in FIG. 4.

DETAILED DESCRIPTION OF THE INVENTION

Referring therefore to FIG. 1, a substrate 10, for example a steel strip, is passed through a coating station 12 to obtain a coating from a fluid lubricant on one or both of oppositely directed surfaces 14, 16. In the embodiment shown in FIG. 1, the coating station 12 includes sprayheads 18 arranged on opposite sides of the substrate 10 (only the upper sprayheads 18 are visible in FIG. 1), although coating on only one side may be utilised where appropriate. A pair of sprayheads 18 are located at longitudinally spaced locations in the direction of movement of the substrate indicated by arrow A to provide successive coatings.

As can best be seen in FIG. 2, each of the sprayheads 18 includes a manifold 20 connected to a pressurized supply 19 of fluid to be applied to the surfaces 14, 16. A series of nozzles 22 are connected to the manifold 20 and each produce a generally conical spray pattern 24. The form of the nozzles 22 is well known and need not be described in further detail. The nozzles 22 are spaced apart along the manifold 20, and thus across the width of the substrate 10 creating a fluid plume, to produce a substantially uniform distribution of the coating fluid to the respective one of the surfaces 14, 16 of the substrate 10.

To monitor the uniformity of coating produced by the sprayheads 185 a laser 30 is located to the same side of the substrate as the manifold 20 that is being monitored. The laser 30 produces a beam 32 of coherent radiation of a particular wavelength, preferably in the direction parallel to the axis of the manifold 20. The laser 30 is positioned such that the beam 32 passes through the overlapping spray patterns 24. Where a plurality of sprayheads 18 are utilized as shown in FIG. 1, each of the sprayheads 18 has an associated laser 30. A suitable laser 30 is one of the SNF Series lasers available from Lasiris.™.

Preferably, the beam 32 is a non-Gaussian, uniform line, produced by a collimated line head 31. A suitable collimated line head is also available from Lasiris.™. Particularly, model C-25 has shown particularly favourable results, having a collimated line length of 25 mm. However, model C-48 (48 mm line length) is also suitable. It will be appreciated that other line lengths may be used depending on the availability of components. A collimated beam 32 is beneficial as the collimator 31 transforms the traditional laser “dot” into a uniform intensity line, which retains a substantially uniform intensity across the beam width. This can be contrasted with the traditional Gaussian beam intensity distribution that has a central “hotspot” and where the intensity weakens towards the beam edges. Moreover, a collimator 31 is ideal for applications requiring a wide range of working distances. However, a traditional Gaussian beam may also be used if desired.

A camera 40 (FIG. 1) is positioned so as to be able to image the spray pattern 24 from the manifolds 20. Where practical, the camera 40 is located above the substrate with a field of view in the direction of motion of the substrate 10. Where this is impractical due to processing considerations, a camera 40 may be disposed to one side of the coating station but spaced from the lasers 30 so as to have a field of view including each spray pattern 24 from the respective sprayheads 18 (see “alternate location” in FIG. 1). Where multiple beams 32 are to be imaged, the camera 40 is positioned out of the horizontal plane passing through the manifolds 20. Typically a displacement of 5 cm to either side of the plane is sufficient to enable each beam to be imaged. Alternatively, the lasers 30 may be staggered in the vertical direction so that the respective beams 32 are vertically offset. Where manifolds 20 are located on both sides of the substrate 10 as shown in FIG. 2, a camera 40 is required on each side in order to image the respective spray patterns.

The camera 40 provides a continuous image to an image processing computer 42 located either within the camera 40 or remotely from the coating apparatus 12. The images obtained by the camera 40 may be processed such as by a narrow band optical filter (not shown) to enhance the contrast between the image produced by the beam 32 and the background The 28 computer 42 processes the images and produces an output to a user interface 46, from which the uniformity of the plume can be determined. The output may be either a pass/fail signal and/or an image that can be viewed by the operator, as shown in more detail in FIG. 4.

In operation, the beam 32 is propagated through the spray patterns 24, and with each of the nozzles 22 functioning correctly, will be uniformly scattered as the beam 32 is propagated. The scattering is induced by the physical characteristics of the spray pattern 24 and the resultant scattering will be viewed by the camera 40 as a bright horizontal band 50 as indicated in FIG. 3( a).

The collimator 31 collimates the beam 32, to provide a uniform intensity line. The uniform beam width is useful because regardless of where the plume crosses the beam 32 the incident light intensity, and thus the scattered light intensity, is substantially constant. This substantially constant scattering facilitates the setting of detection thresholds in the camera 40 and computer 42 for monitoring the spray patterns 24 and plume. A standard beam having a Gaussian intensity distribution may be used but it is sensitive to alignment. If the plume wanders off the axis of the laser beam 32, the incident light intensity drops off. This can lead to increased error in detecting disruptions in the spray pattern 24.

The camera 40 therefore obtains images and checks the images for the presence of such a horizontal band 50. As will be described in more detail below with reference to FIG. 5, the image processing isolates the horizontal band 50 and determines the uniformity of the intensity along the horizontal extent of the sprayheads 18. Discontinuities in the image are indicative of discontinuities on the sprayhead and therefore these may be monitored and correlated with malfunction of the nozzles 22.

Wherever discontinuity is detected, remedial action may be taken and the uniformity of the spraying restored.

The image obtained from the camera 40 is formed from a matrix of pixels each having a discrete value associated with the intensity of the pixel. This format of image allows information on the spray pattern 24 to be extracted and utilized in the production process.

The signal processing is performed using selected procedures from commercially available imaging software such as that available from DVT Frameworks. As shown in FIGS. 4 and 5, after the image is captured, initially the region of interest is isolated by defining a window 60, and the distribution of the intensities associated with pixels within the defined window 60 is assessed. The windows may be preset in regions of the image where a plume is to be expected to facilitate automatic monitoring. Using the intensity distribution, a threshold to accord a light pixel versus a dark pixel is set. For example, those regions where scattering is present would be considered a light pixel and those where no scattering is present would be considered a dark pixel. Adjustment of the threshold may also accommodate different operating conditions, spray densities and distance from the camera 40.

Having established the threshold, the image is processed to look for regions of continuous brightness, typically referred to a “blobs”. This can be performed using the blob tools available on the commercial software to identify a number of blobs present in the window 60. If there is a uniform distribution of spray along the sprayhead then a single blob would be detected indicating a continuous region of brightness from one end of the sprayhead 18 to the other as shown in FIG. 3( a) (i.e. the horizontal band 50). If however, there is a blocked nozzle or a reduced spray in certain areas, as shown in FIG. 3( b), then two or more blobs (e.g. 52 and 54 shown in FIG. 3( b)) will be identified indicating a discontinuity in the spray pattern 24. Similarly, if no blobs are observed then either the laser 30 is faulty or there is no spray. The detection of a plurality of blobs or no blobs can then be used to signal a fault and initiate remedial action.

It will be seen therefore that a simple monitoring of the propagation of the beam 32 in a spray pattern 24 formed by successive spray nozzles 22 provides an effective indication of the uniformity of the spray between separate nozzles 22, and allows the malfunction of a nozzle 22 to be detected and corrected. The identification may be done manually or may be used automated through image processing techniques that allow an claim to be initiated for corrective action. The imaging software is of course integrated with the spray control so that it is only responsive when the spray is to be delivered.

The system works best with a fine spray, as produced by an electrostatic sprayer (charging of the spray drops causes them to break up into finer drops than initially emitted from the nozzle), or other misting-type applicator.

The system functions best with a fine spray because the spray plume is “optically thin”. This allows most of the light to pass through the plume and only a small fraction is scattered. Therefore a segment at the far end of the plume sees about the same light intensity, and scatters about the same fraction, as a plume segment near the beginning of the plume. The device may be used with other sprays with suitable compensation of the threshold to accommodate light absorption in the spray.

Although the invention has been described with reference to certain specific embodiments, various modifications thereof will be apparent to those skilled in the art without departing from the spirit and scope of the invention as outlined in the claims appended hereto. 

1-13. (canceled)
 14. A system for monitoring the application of coating to a surface of a substrate, the coating being applied as a spray from a plurality of nozzles spaced apart along at least one dimension of the substrate, the system comprising: a coherent radiation source arranged to direct a beam of coherent radiation through said spray; an imaging device for obtaining an image of said beam as it propagates through said spray, and a computing device having a processor to receive an input from said imaging device and process said image in order to determine variations in a characteristic indicative of the presence of said spray.
 15. A system according to claim 14 further comprising an interface connected to said computing device, said interface permitting a user to interact with said image.
 16. A system according to claim 14 wherein said processing identifies discontinuities in said characteristic.
 17. A system according to claim 16 wherein said processing determines the lack of continuity of areas of said image in excess of a predetermined value, which are utilized to identify discontinuities in said characteristic.
 18. A system according to claim 16 wherein said processing identifies the scattering of said radiation by said spray of coating, and isolates a region with scattering below a predetermined threshold to identify discontinuities in said characteristic.
 19. A system according to claim 14 wherein said coherent radiation source is a laser beam generated by a laser.
 20. A system according to claim 19 wherein said laser further comprises a collimator to produce a non-Gaussian, substantially uniform intensity line from said laser beam.
 21. A system according to claim 14 wherein said imaging device is a camera.
 22. A system according to claim 21 wherein said camera is a smart camera and said computing device and said processor are operated by said smart camera.
 23. A system according to claim 14 wherein said imaging device is positioned with its field of view along an intended path of said substrate.
 24. A system according to claim 14 wherein said imaging device is disposed to one side of said substrate with its field of view along an angle to an intended path of said substrate.
 25. A system according to claim 14 further comprising a second coherent radiation source and a second imaging device, both of which are all arranged to monitor the application of a coating to a second surface of said substrate.
 26. A system according to claim 14 wherein said plurality of nozzles are spaced along a plurality of sprayheads to produce a plurality of sprays, said system further comprises a coherent radiation source for each of said sprays to direct a beam of coherent radiation through each of said sprays, and wherein said imaging device is arranged to capture at least two of said beams as they propagate through respective sprays in the same image.
 27. A system according to claim 26 wherein at least two of said plurality sprayheads are offset in a vertical direction with respect to each other and said imaging device is positioned with its field of view substantially parallel to an intended path of said substrate.
 28. A system according to claim 26 wherein said plurality of sprayheads are arranged vertically coincident with each other and said imaging device is offset vertically therefrom.
 29. An apparatus for applying coating to a substrate, the apparatus comprising: a coating station having a feeder for continuously feeding said substrate through said apparatus; at least one spray head connected to said coating station and positioned a predetermined distance from said substrate, said sprayhead having a plurality of nozzles, said nozzles being connected to a source of coating to enable coating to be fed through said nozzles to produce a spray of coating, said spray of coating being applied to a surface of said substrate; at least one coherent radiation source arranged to direct a beam of coherent radiation through said spray as said spray is applied to said substrate; an imaging device for obtaining an image of said beam as it propagates through said spray; and a computing device having a processor for processing said image to determine variations in a characteristic indicative of the presence of said spray.
 30. An apparatus according to claim 29 further comprising an interface connected to said computing device, said interface permitting a user to interact with said image.
 31. An apparatus according to claim 29 having a pair of sprayheads each positioned on respective sides of said substrate, to spray at oppositely directed surfaces of said substrate; a pair of coherent radiation sources each arranged to direct respective beams of coherent radiation through respective sprays of respective sprayheads; and a pair of imaging devices, each imaging device being positioned to obtain respective images of respective beams as they propagate through respective sprays; wherein said processor processes a pair of images to determine variations in a characteristic indicative of the presence of respective sprays applied to each surface.
 32. An apparatus according to claim 29 wherein said coherent radiation source is a laser beam generated by a laser.
 33. An apparatus according to claim 32 wherein said laser further comprises a collimator, said collimator altering said laser beam to produce a non-Gaussian, substantially uniform intensity line.
 34. An apparatus according to claim 29 wherein said imaging device is a camera.
 35. An apparatus according to claim 34 wherein said camera is a smart camera and said computing device and said processor are operated by said smart camera.
 36. An apparatus according to claim 29 wherein said imaging device is positioned with it field of view along the path of travel of said substrate.
 37. An apparatus according to claim 29 wherein said imaging device is disposed to one side of said substrate with its field of view along a angle to the path of travel of said substrate.
 38. An apparatus according to claim 29 wherein said plurality of nozzles are spaced along a plurality of sprayheads to produce a plurality of sprays, said system further comprises a coherent radiation source for each of said sprays to direct a beam of coherent radiation through each of said sprays, and wherein said imaging device is arranged to capture at least two of said beams as they propagate through respective sprays in the same image.
 39. An apparatus according to claim 38 wherein at least two of said plurality sprayheads are offset in a vertical direction with respect to each other and said imaging device is positioned with its field of view substantially parallel to an intended path of said substrate.
 40. An apparatus according to claim 38 wherein said plurality of sprayheads are arranged vertically coincident with each other and said imaging device is offset vertically therefrom. 